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. 2012 Oct 18;8(10):e1002736. doi: 10.1371/journal.pcbi.1002736

Membrane-Elasticity Model of Coatless Vesicle Budding Induced by ESCRT Complexes

Bartosz Różycki 1,2, Evzen Boura 3, James H Hurley 3, Gerhard Hummer 1,*
Editor: Vijay S Pande4
PMCID: PMC3475702  PMID: 23093927

Abstract

The formation of vesicles is essential for many biological processes, in particular for the trafficking of membrane proteins within cells. The Endosomal Sorting Complex Required for Transport (ESCRT) directs membrane budding away from the cytosol. Unlike other vesicle formation pathways, the ESCRT-mediated budding occurs without a protein coat. Here, we propose a minimal model of ESCRT-induced vesicle budding. Our model is based on recent experimental observations from direct fluorescence microscopy imaging that show ESCRT proteins colocalized only in the neck region of membrane buds. The model, cast in the framework of membrane elasticity theory, reproduces the experimentally observed vesicle morphologies with physically meaningful parameters. In this parameter range, the minimum energy configurations of the membrane are coatless buds with ESCRTs localized in the bud neck, consistent with experiment. The minimum energy configurations agree with those seen in the fluorescence images, with respect to both bud shapes and ESCRT protein localization. On the basis of our model, we identify distinct mechanistic pathways for the ESCRT-mediated budding process. The bud size is determined by membrane material parameters, explaining the narrow yet different bud size distributions in vitro and in vivo. Our membrane elasticity model thus sheds light on the energetics and possible mechanisms of ESCRT-induced membrane budding.

Author Summary

Lipid membranes enclose the cytosol of biological cells and compartmentalize their interior. Vesicles are used to transport membrane proteins between cellular compartments. The ESCRT protein machinery induces the creation of such vesicles away from the cytosol. The resulting vesicles are uncoated by protein. Upon vesicle scission and release into the endosome, the ESCRT proteins are recycled into the cytosol. We develop a membrane-elasticity model that captures this budding process. The model reproduces the vesicle morphologies observed in fluorescence microscopy images, and identifies the energetic driving force of vesiculation. We also characterize possible mechanisms of ESCRT-induced membrane budding. The size of the resulting vesicles is determined by membrane material parameters, explaining the narrow yet different bud size distributions in vitro and in vivo. Our membrane elasticity model thus provides insight into the energetics and mechanisms of uncoated vesicle formation.

Introduction

Lipid membranes enclose the cytosol of biological cells and compartmentalize their interior. The structure and contents of cellular membranes are actively controlled to sustain the vital functions of the cell. Transport vesicles are used to traffic membrane-bound proteins between cellular compartments. The best-characterized pathways of vesicle formation include those facilitated by BAR domain proteins [1] and by the coat protein clathrin with its adaptors [2]. Coat proteins impose their curved shape onto the membrane, thereby promoting vesicle curvature in an intuitively straightforward and computationally well-characterized process [3][5]. In the degradative transport of membrane proteins from endosomes to lysosomes (Fig. 1), small patches of the endosomal membrane bud into the interior (lumen) of the endosome and detach, forming intralumenal vesicles (ILVs) [6], [7]. This pathway is catalyzed by the cytosolic Endosomal Sorting Complex Required for Transport (ESCRT) [8][10]. The ESCRT proteins are not internalized in ILVs, but rather recycled continuously in the cytosol [11], [12]. To avoid the consumption of ESCRT proteins within the ILVs, these vesicles contain no protein coat to template their shape. Rather, these vesicles are initially formed as buds whose necks are stabilized by an assembly of ESCRT-I and -II [13]. As the assembly matures with the incorporation of ESCRT-III, the bud neck is cleaved from the cytosolic side, leaving ESCRTs in the cytosol and the detached spherical ILVs in the lumen of the endosome. Because this process involves no protein coat, the shape and energy of the mature buds must be governed primarily by membrane mechanical properties.

Figure 1. ESCRT protein assemblies (blue) facilitate the sorting of ubiquitinated membrane proteins (green) and formation of intralumenal vesicles (ILV).

Figure 1

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The ESCRT proteins assemble on the membrane side opposite the vesicle bud (C) and do not enter the ILV lumen for possible recycling (D). Energy input from ATP hydrolysis accelerates disassembly of the ESCRT machinery (D), but is not required in steps (A–C).

Until recently, the membrane remodeling functions of ESCRT were attributed only to ESCRT-III proteins, which assemble on liposomes in vitro [14], induce the ILV formation in giant unilamellar vesicles (GUVs) [12] and cause the plasma membrane to bud and tubulate when overexpressed in cells [15]. Based on these experimental observations, membrane deformations induced by ESCRT-III have been modeled [12] and studied theoretically [16]. An unresolved problem of these models was their inability to explain how the ESCRT-III proteins can be recycled from self-induced buds or tubes.

Recent in vitro experiments showed, however, that ESCRT-I and -II together are responsible for vesicle budding [13]. In these experiments, vesicle budding could be induced at physiological concentrations (15 nM) of ESCRT-I and -II. Fluorescence microscopy showed ESCRT-I and -II to be colocalized in the neck region of the buds (Fig. 1C), where they were shown to recruit ESCRT-III. The latter proteins then induced membrane scission [12]. Importantly, the ESCRT proteins were not found in the bud lumen. In this way, the ESCRT machinery that facilitates membrane budding and scission is not consumed in the process of ILV formation (Fig. 1D). Moreover, with ESCRT binding restricted to the neck region, the principal part of vesicle buds in vitro is thus bare lipid membrane.

Fluorescence microscopy [13] also showed that membrane-bound ESCRT proteins form microdomains on vesicle membranes (Fig. 1B and 1C). The lipid composition of these domains likely differs from that in the ESCRT-free membrane portions because ESCRTs bind specifically to certain charged lipids (PI3P) and could employ raft-favoring lipids and cholesterol to facilitate membrane budding [17], [18].

These two experimental observations of (i) the formation of ESCRT microdomains on the membrane and (ii) the formation of coatless buds (with ESCRT proteins localized in the bud neck) jointly form the basis for a phenomenological model of ESCRT-induced budding. Observation (i) provides us with the starting point for the budding process and motivates a mechanism that can provide the large energy necessary for membrane deformation. Observation (ii) determines the end point of the budding pathway. In our model, we assume that the ESCRT-I-II supercomplexes have an enhanced affinity for binding to saddle-shaped membrane regions, and that a line tension acts on the outer boundary of an ESCRT-sequestered membrane domain. We cast our model in the framework of membrane elasticity theory. A bending elastic model of lipid bilayers was previously used to study the energetics of a possible mechanism of ESCRT-III induced fission of nascent vesicles [19]. Here we employ a similar approach to study the ESCRT-I-II induced formation of vesicle buds.

The analytical solutions of our model allow us to map out different membrane morphologies over a range of possible physical parameters. We identify a regime of membrane bending parameters and line tensions for which the minimum energy configurations are coatless membrane buds with ESCRTs localized in the bud neck. These minimum energy configurations closely resemble the fluorescence images observed in experiment [13]. Within our model, we also identify energetically and kinetically feasible budding pathways, and propose a three-stage mechanism of ESCRT-driven budding: (i) membrane-bound ESCRT-I-II complexes form clusters, or domains, and induce a line tension on the domain boundaries through local segregation of lipids; (ii) as the domain boundary energy exceeds a threshold level, the membrane patch sequestered by the ESCRT assemblies buckles and forms a bud; (iii) the ESCRT-I-II complexes scaffold the bud neck and thus stabilize a neck diameter optimized for ESCRT-III protein binding and bud scission. To validate the model, we compare its predictions for bud shapes, sizes, and formation kinetics to experiment [13], [20]. We also relate our model to recent experiments probing ESCRT-induced lipid segregation in membranes [21].

Model

In the framework of membrane elasticity theory, the energy of membrane deformations consists of the mean curvature term

graphic file with name pcbi.1002736.e001.jpg (1)

and the Gaussian curvature term

graphic file with name pcbi.1002736.e002.jpg (2)

where Inline graphic and Inline graphic are the mean and Gaussian bending rigidity moduli, respectively; Inline graphic and Inline graphic are the principal local curvatures; Inline graphic is the spontaneous curvature; and the integrals are performed over the membrane surface Inline graphic [22]. For uniform membranes with fixed topology, the energy term Inline graphic does not depend on membrane shape. Consistent with in vitro experiments [13], we will consider symmetric lipid bilayers with no spontaneous curvature, Inline graphic.

Eq. (1) implies that the energetic cost of forming a vesicle bud [23][27] is approximately Inline graphic, which exceeds Inline graphic for typical membrane bending rigidities Inline graphic. This large energetic cost effectively eliminates random thermal fluctuations as a main factor. Instead, the energetic cost of the nascent vesicle bud has to be offset by the molecular machinery that drives the budding process. In ESCRT-induced budding, the source of this offset energy is provided by the binding of the ESCRT proteins to the membrane. But unlike BAR domains or clathrin proteins, the ESCRT machinery does not seem to use the scaffold mechanism as the primary mode of action. Indeed, the scaffold mechanism cannot easily account for the significantly different bud radii in vitro (Inline graphicm [13]) and in vivo (Inline graphic [20]), and appears to be contradicted by the experimental observation that the ESCRT proteins colocalize in the neck of buds.

How does the ESCRT machinery deform a flat membrane patch into a bud [28]? There are two relevant observations that help answer this question. Firstly, there is increasing evidence that the insertion of amphipathic, cationic peptide segments into the lipid bilayer can induce negative Gaussian curvature [29][31], which is a characteristic of the bud necks where the ESCRT proteins localize. The Vps37 subunit of ESCRT-I has such a cationic helix at its N-terminus [32], as does the Vps22 subunit of ESCRT-II [33]. It is therefore possible that the ESCRT-I-II proteins generate negative Gaussian curvature by inserting amphipathic and cationic segments into the membrane. In the lowest order of approximation, the resulting curvature-dependent binding energy,

graphic file with name pcbi.1002736.e016.jpg (3)

is proportional to the membrane Gaussian curvature Inline graphic integrated over an ESCRT-rich membrane patch Inline graphic, where Inline graphic is a coupling constant. Remarkably, we also arrive at an energy term that is formally equivalent to Eq. (3) on an entirely different route. If we assume that by binding to the membrane, the ESCRT-I-II proteins locally perturb its Gaussian bending modulus according to Eq. (2), then the parameter Inline graphic can be understood as the Gaussian bending modulus contrast Inline graphic. The energy term in Eq. (3) thus accounts for both the preferential binding to saddle-shaped features of the membrane and for changes in the Gaussian bending modulus in response to binding, with different interpretations of the constant Inline graphic.

The second relevant observation is that late endosomes contain raft-like domains that are rich in cholesterol and sphingomyelin [34][36]. The in vitro experiments [13] were performed on vesicles containing cholesterol, raft-favoring lipids and PI3P, which is consistent with the possibility that ESCRTs could use lipid rafts or domains to promote membrane budding [17], [18]. The ESCRT proteins could bind to pre-existing rafts or induce lipid domain formation. In fact, proteins with multiple lipid binding sites can induce lipid segregation in membranes close to the demixing point [37][40]. Lipid segregation has been suggested as a factor driving scission in endocytosis [41]. The enhancement of lipid segregation upon protein binding is primarily an entropic effect. Lipid segregation has to overcome an entropic penalty to move away from a perfectly mixed state. This penalty is reduced by concentrating certain lipids through preferential binding because the entropic cost of rearranging the resulting clusters of protein-bound lipids is smaller than that of rearranging individual lipids.

We consider a single lipid-segregated domain Inline graphic. A line tension Inline graphic acts on the boundary Inline graphic of this domain, where the corresponding energy is proportional to the length of the boundary line

graphic file with name pcbi.1002736.e026.jpg (4)

To quantify the preferential binding of ESCRTs to lipid rafts or domains, we introduce an additional energy term in the spirit of mean field theory

graphic file with name pcbi.1002736.e027.jpg (5)

Here, Inline graphic is an effective ESCRT binding free energy per unit area, and Inline graphic denotes the intersection of the lipid-segregated domain Inline graphic and the ESCRT-rich domain Inline graphic on the membrane, where we assume that the latter is a subset of the former, Inline graphic. In the following, we assume the shapes of Inline graphic and Inline graphic to be circular and ring-shaped, respectively.

As we show below, a minimal model of ESCRT proteins inducing or enhancing lipid segregation can explain central experimental results, in particular the narrow yet different bud-size distributions in vivo and in vitro. Moreover, the line tension on the boundaries of the lipid-segregated membrane domains [42][44] can also provide the large energetic driving force for vesicle budding [45][48].

Our model is defined by the energy functional

graphic file with name pcbi.1002736.e035.jpg (6)

which combines the energy terms in Eqs. (1), (3), (4), and (5). The four corresponding parameters Inline graphic, Inline graphic, Inline graphic, and Inline graphic depend on membrane lipid composition, on external conditions such as temperature, and on ESCRT molecular properties, which are not entirely understood yet. Therefore, the model parameters can take different values depending on the molecular details of the ESCRT-membrane system. We thus use the spherical cap approximation [45], [49] to derive analytical solutions that allow us to map out the entire parameter space of the model. We then minimize the energy functional Eq. (6) with respect to the membrane shape and the ESCRT cluster location, and investigate the membrane states, or morphologies, that are stable in different parameter regimes. Interestingly, we find a range of physically meaningful parameters in which the minimum energy states closely resemble the fluorescence images in Ref. [13]. We also investigate possible budding pathways that lead without activation barriers from a flat membrane state to the coatless membrane bud with ESCRTs localized in the neck.

Results

In the following, we first develop an approximate analytic treatment that accurately captures the energetics. We then report the results of numerical calculations that allow us to test the analytical solutions and to provide detailed information about the bud shapes. Finally, we analyze possible budding pathways.

Energetics and morphology diagrams

To make our model analytically tractable, we applied the spherical cap approximation, which is known to capture the energetics of unassisted membrane budding [45], [49]. In the spherical cap approximation, the energy functional Eq. (6) becomes a simple function whose minima can be found analytically (see Methods). The phase diagram that results from the energy minimization for Inline graphic displays three regimes which are shown in Fig. 2. For small line tensions Inline graphic (left side of Fig. 2), the membrane resists bending and remains flat. The lipid-segregated domain Inline graphic and the ESCRT-rich domain Inline graphic colocalize entirely. For large line tensions Inline graphic and large binding energies Inline graphic (top right corner of Fig. 2), the membrane buckles and forms an ESCRT-covered bud. Again Inline graphic and Inline graphic colocalize. For large Inline graphic and small Inline graphic (bottom right corner of Fig. 2), the minimum energy configurations are coatless buds with ESCRTs localized in the bud neck.

Figure 2. Membrane morphology diagram from the analytical solution obtained for the spherical cap approximation (lines) and from numerical energy minimizations (symbols).

Figure 2

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Results are shown for a Gaussian bending modulus fixed at Inline graphic. The green squares represent the flat membrane state. The magenta triangles correspond to ESCRT-coated membrane buds. The orange circles represent bare lipid buds with ESCRTs localized in the bud neck. The black solid lines are the coexistence lines, and the black dotted line represents the spinodal at which the energetic barrier to bud formation vanishes. Exemplary membrane shapes are shown for indicated points. The red and blue lines represent lipid domains and ESCRT-rich domains, respectively.

Membrane shape

To test the spherical cap approximation and to calculate bud shapes, we minimized the energy functional Eq. (6) numerically with respect to the membrane shape and the location of the ESCRT cluster (see Methods). To distinguish different morphologies of the minimum energy configurations, we introduced the area fraction Inline graphic, where Inline graphic and Inline graphic denote the areas of the lipid segregated domain Inline graphic and the ESCRT-rich domain Inline graphic, respectively. We grouped all the minimum energy configurations found numerically into three distinct categories: (i) flat membrane domains with zero bending energy and area fraction Inline graphic, (ii) ESCRT-coated buds with bending energy Inline graphic and area fraction Inline graphic, and (iii) coatless buds with Inline graphic, small area fraction Inline graphic, and the ESCRT cluster located primarily in the bud neck region. The resulting morphology diagram agrees very well with the diagram based on the spherical cap approximation (Fig. 2).

The spherical cap model predicts discontinuous transitions between the different morphological phases, with a kink in the minimum energy at the transition lines. In the complete model, however, the kink is rounded at the transition line Inline graphic due to the finite-size of the bud neck (Fig. 3A).

Figure 3. Relation between energetic and geometric properties, obtained by numerical minimization of the energy functional Eq. (6) for fixed parameters Inline graphic and Inline graphic.

Figure 3

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(A) Minimum energy Inline graphic rescaled by the membrane bending rigidity Inline graphic as a function of the ESCRT binding energy Inline graphic rescaled by the area Inline graphic of the lipid-segregated domain. (B) Minimum energy Inline graphic as a function of the cosine of the membrane tangent angle Inline graphic along the lines of longitude at the boundary of the ESCRT-coated domain. (C) Inline graphic as a function of the binding energy Inline graphic rescaled by the area Inline graphic of the lipid-segregated domain Inline graphic. (D) Inline graphic as a function of the area fraction Inline graphic, where Inline graphic is the area of the ESCRT-rich domain Inline graphic.

To additionally quantify the bud morphologies, we determined the tangent angle Inline graphic (see Methods) along the longitude at the boundary of the ESCRT-coated domain. The angle Inline graphic as well as the area fraction Inline graphic exhibit an abrupt change at the transition line Inline graphic, as shown in Fig. 3, which further justifies the distinction between ESCRT-coated buds and uncoated buds.

It is instructive to have a closer look at the membrane buds shown in the bottom right corner of Fig. 2. The principal part of these buds is coatless membrane, and the ESCRT cluster is localized only in the bud neck. These coatless buds assume the shape of a sphere. The geometry of the bud neck follows that of a catenoid, a minimal surface with no mean curvature, Inline graphic, and thus zero bending energy [24][27]. As a result, the bending energy of the buds approaches the bending energy of a spherical vesicle, Inline graphic. We note that our calculated bud shapes, as shown in the top right corner of Fig. 2, resemble the tomographic images of early endosomes [20] and the fluorescence images of GUV buds observed in vitro [13].

Budding mechanisms

Within the framework of the spherical cap approximation, we also analyzed possible budding pathways. We focused in particular on activation-less pathways along which the buds grow without having to cross significant energy barriers (see Methods). This analysis revealed a three-stage mechanism of ESCRT-mediated membrane budding. In stage (i) the ESCRT-rich domain Inline graphic and the lipid-segregated domain Inline graphic colocalize entirely on the flat membrane if Inline graphic. As the domain radius increases beyond Inline graphic, the energy of the flat domain becomes larger than the energy of an ESCRT-covered bud. As the domain radius increases to Inline graphic, the barrier between these membrane states vanishes entirely and the system enters into stage (ii) in which the flat membrane domain buckles and forms an ESCRT-covered bud. The resulting bud has a radius

graphic file with name pcbi.1002736.e089.jpg (7)

which, interestingly, is determined by membrane material parameters. In stage (iii) the ESCRTs coalesce into the bud neck with no energy barriers if Inline graphic. The third stage is driven by the energy Inline graphic of the ESCRT preferential binding to membrane regions with negative Gaussian curvature. Importantly, in stage (iii), the bud is cleared of ESCRTs for possible recycling.

If Inline graphic, the mechanism of ESCRT-mediated membrane budding is different. The flat membrane with ESCRTs bound is then unstable and the system evolves spontaneously to a transient state, in which ESCRT-free buds with radius Inline graphic are formed. The mini-buds, induced by a strong binding preference Inline graphic to saddle-shaped membrane structures, are next squeezed bigger by line tension Inline graphic if the radius of the ESCRT-coated membrane patch is smaller than Inline graphic. The latter condition puts an upper bound on the ESCRT-free bud radius Inline graphic. Interestingly, on this budding pathway the ESCRTs never coat the bud. We note, however, that this pathway is somewhat problematic since the linear approximation in Eq. (3) may not be applicable for large parameters Inline graphic. In addition, effects of finite membrane thickness cannot be ignored in this regime.

Discussion

The detailed physical mechanisms used by the ESCRT machinery to control membrane budding are currently unknown. This lack of knowledge has motivated us to consider a simple, phenomenological model for ESCRT-induced membrane budding. Our model is based on well-established physical principles to ensure robustness. Following earlier studies of membrane tubulation [16] and fission [19] driven by ESCRT-III proteins, we have cast our model in the framework of membrane elasticity theory. The key assumption in our model is that ESCRTs induce or enhance the formation of raft-like domains in lipid membranes. Indeed, recent total internal reflection fluorescence (TIRF) images show that the ESCRT-II proteins induce lipid phase separation in model membranes with endosome-like composition [21]. These direct experimental observations thus support a central element of our theoretical model. However, to test and further quantitate our model will require additional studies of ESCRT-membrane interactions. In particular, line tension measurements would provide critical input in building a fully quantitative description of the budding process. In addition, studies of the different components of the ESCRT system, including modifications such as Vps20 myristoylation, should provide further guidance at which stage and to what extent lipid phase separation is induced. The TIRF experiments [21] indicate interesting variations, with the yeast ESCRT-II protein complex forming somewhat smaller and more numerous clusters than the human ESCRT-II protein complex under the same conditions. Ultimately, it will be important to determine if membrane curvature is induced in a way consistent with our theoretical analysis. Such measurements would provide critical tests to what extent our model captures ESCRT-induced budding, and would help in its quantitation and refinement.

The energetic analysis of our model suggests a three-stage mechanism of vesicle budding induced by the ESCRT proteins. In the first stage, the ESCRT-I-II binding induces lipid phase segregation, consistent with the TIRF experiments [21]. We speculate that in this stage, ESCRT-I-II complexes loosely assemble on the membrane to form clusters or domains. The ESCRT-membrane interactions enhance lipid segregation in the membrane and induce a line tension Inline graphic on the domain boundaries. Once the lipid-segregated membrane domain exceeds a critical size, as determined by membrane material parameters according to our model, the process enters the second stage. Beyond a size threshold set by the ratio Inline graphic, the energy barrier to membrane shape deformation disappears, and the membrane patch sequestered by ESCRTs buckles and forms a bud. In the third stage, according to our energy function, the ESCRT-I-II complexes concentrate in the neck of the newly formed bud. This final step is driven the ESCRT binding energy Inline graphic to the membrane portions with negative Gaussian curvature. While our model lacks molecular detail of this curvature-dependent binding, recent experiments [29][31] suggest possible mechanisms. In particular, it could be caused by the insertion of amphipathic and cationic segments of the membrane-bound ESCRT proteins into the membrane, or by the formation of an assembly whose shape is complementary to that of the bud neck [50]. The formation of neck-coating assemblies by the ESCRT-I-II complexes not only would help recruit ESCRT-III proteins for scission, but could also clear the ESCRT-I-II proteins from the bud lumen and set them up for recycling.

The third stage of the budding process described above is dynamically feasible within the overall time scale of the process. The diffusion coefficient of membrane proteins is of order Inline graphic [51]. Provided a gradient to the bud neck region, the process of clearing in vitro buds with radius Inline graphic [13] would be completed within Inline graphic. The clearing process would be two orders of magnitude faster for the in vivo buds with radius Inline graphic [20].

One immediate consequence of the three-stage mechanism is that the complete buds have a radius Inline graphic that is determined by membrane material parameters, namely membrane rigidity Inline graphic and line tension Inline graphic. Therefore, the bud radius Inline graphic attains a particular value for a vesicle at given conditions, which explains the narrow distribution of bud sizes observed both in vitro [20] and in vivo [13]. We note, however, that both the line tension Inline graphic and the bending rigidity Inline graphic may be affected by details of the ESCRT-membrane interactions, which could explain small ILV size variations in response to mutations [52].

Despite the 40-times smaller radius Inline graphic, the in vivo buds have the same bending energies and shapes as the buds observed in vitro. This conclusion is a direct consequence of the scale invariance of the membrane bending energy Eq. (1). However, the line tensions necessary to induce vesicle budding, Inline graphic, are different. For in vivo buds with radius Inline graphic and bending rigidity Inline graphic [53], we estimate Inline graphic; for in vitro buds with Inline graphic, we get Inline graphic assuming the same membrane rigidity Inline graphic. Line tensions in this range have been measured in GUVs [42], [47].

We note that the bending rigidity of early endosomes [53] is an order of magnitude lower than the bending rigidity of lipid membranes in the liquid-ordered phase [47], [54]. This difference in mechanical properties may be caused by variations in the composition and by the presence and activity of proteins in the membrane of endosomes. The membrane-sculpting protein Sar1 of the COPII complex, for example, has been shown to lower the membrane rigidity below Inline graphic [55]. The rigidity of fluid membranes has also been shown to decrease gradually with increasing concentration of the HIV-1 fusion peptide in the bilayer [56].

The three-stage budding process discussed above occurs if the Gaussian bending modulus contrast Inline graphic is limited to a window Inline graphic. This relation puts an upper bound on the binding energy Inline graphic. For typical bending rigidities Inline graphic and line tensions Inline graphic, the required energy Inline graphic is of order Inline graphic per Inline graphic or smaller.

If the affinity of ESCRTs to regions with negative Gaussian curvature is high, Inline graphic, our model predicts a different budding pathway. In this case, flat ESCRT-coated membrane domains are unstable, and small ESCRT-free buds form spontaneously. The mini-buds induced by a strong binding preference Inline graphic to saddle-like membrane shapes can next be squeezed bigger by line tension Inline graphic. The latter transition occurs if the radius of the ESCRT-coated domain does not exceed Inline graphic. The resulting ESCRT-free buds have a radius Inline graphic. For Inline graphic and Inline graphic as above, we get the bud radius Inline graphic smaller than approximately Inline graphic, which is consistent with the size of late endosome buds, Inline graphic [20].

In contrast to the three-stage mechanism, in the pathway starting with mini-buds the ESCRTs never enter the bud lumen. It is thus tempting to picture this alternative budding route as follows: ESCRT-0 and -I bind to the membrane with Inline graphic and the membrane remains flat. When ESCRT-II proteins bind to ESCRT-I and to the membrane, Inline graphic becomes larger than Inline graphic and the ESCRT-free membrane buds are formed spontaneously. The condition for forming a finite-size, ESCRT-free bud is that the radius of the ESCRT patch at the ESCRT-II arrival can not exceed Inline graphic. We notice, however, that this pathway might be an artifact of our model since the linear approximation in Eq. (3) could be inapplicable for large Inline graphic. Nevertheless, we cannot entirely exclude this alternative pathway.

Overall, we favor the three-stage mechanism as a possible route for ESCRT-induced budding. It concisely explains the uniform bud sizes seen in experiment, and makes quantitative and testable predictions for their dependence on physical parameters. In particular, according to Eq. (7) the vesicle bud radius Inline graphic should increase linearly as a function of the ratio Inline graphic. Since the line tension Inline graphic depends sensitively on temperature [42], it should be possible to test this theoretical prediction in future experiments on GUVs.

A key element of the model is the Gaussian bending energy Inline graphic. Because of experimental difficulties, our understanding of Gaussian curvature effects is rather limited. However, factors affecting the Gaussian bending modulus [57], [58] or enhancing the binding to membranes with negative Gaussian curvature [29][31] have been established. As detailed structural models of the full-length ESCRT protein supercomplexes emerge [50], [59], it will be important to identify the interactions responsible for the preferential association of the ESCRT proteins to saddle-shaped bud-neck membrane regions. It may also be possible to study binding of ESCRT proteins or protein fragments to model systems with negatively curved membranes [29][31]. In this way, one could gain a microscopic quantification of the parameter Inline graphic, putting it on similar footing as the other membrane-bending terms.

Methods

We consider only axisymmetric vesicle buds as the lowest energy shape by symmetry. Their surface is described in terms of two parameters, the angle Inline graphic of rotation around the axis of symmetry, and the arc length Inline graphic along longitudes. The vesicle bud surface then has Cartesian coordinates Inline graphic, Inline graphic and Inline graphic, where Inline graphic and Inline graphic and Inline graphic is the distance from the Inline graphic-axis, which is the axis of symmetry of the bud. One can introduce a tangent angle Inline graphic such that Inline graphic and Inline graphic. In this parametrization, the principal local curvatures are Inline graphic and Inline graphic [60], [61]. Therefore, in this parametrization, Eq. (1) reads

graphic file with name pcbi.1002736.e163.jpg (8)

The lower limit of integration, Inline graphic, corresponds to the “south pole” of the vesicle bud at which Inline graphic. With these boundary conditions we have Inline graphic and Inline graphic. The upper limit of integration in Eq. (8), Inline graphic, corresponds to the bud rim, where Inline graphic and Inline graphic to connect the bud smoothly to a flat membrane at a distance Inline graphic from the axis.

The boundaries of the ESCRT-occupied membrane patch are located at Inline graphic and Inline graphic with Inline graphic. Eq. (3) takes the following form in the arc-length parametrization,

graphic file with name pcbi.1002736.e175.jpg (9)

which simplifies to

graphic file with name pcbi.1002736.e176.jpg (10)

In this parameterization, the energy terms in Eqs. (4) and (5) become

graphic file with name pcbi.1002736.e177.jpg (11)

and

graphic file with name pcbi.1002736.e178.jpg (12)

The total energy is Inline graphic.

Numerical calculations

It is convenient to use dimensionless variables in numerical calculations. Here we introduce

graphic file with name pcbi.1002736.e180.jpg (13)

and Inline graphic with Inline graphic. With these dimensionless variables, the boundaries of the ESCRT-occupied membrane patch are described by parameters Inline graphic and Inline graphic, where Inline graphic. The energy functional

graphic file with name pcbi.1002736.e186.jpg (14)

depends then on the bud shape, which is described by

graphic file with name pcbi.1002736.e187.jpg (15)

on the domain location as given by Inline graphic and Inline graphic; and on three dimensionless parameters

graphic file with name pcbi.1002736.e190.jpg (16)
graphic file with name pcbi.1002736.e191.jpg (17)

and

graphic file with name pcbi.1002736.e192.jpg (18)

In deriving the equations above we used a relation between the contour length Inline graphic and the membrane area Inline graphic, namely

graphic file with name pcbi.1002736.e195.jpg (19)

The membrane energy (14) is minimized numerically with respect to the bud shape Inline graphic and the domain boundaries Inline graphic and Inline graphic using a simulated annealing method. To this end, the function Inline graphic is assumed to be smooth at Inline graphic and approximated by a Fourier series

graphic file with name pcbi.1002736.e201.jpg (20)

that fulfills the boundary conditions Inline graphic and Inline graphic. Here, Inline graphic is the number of Fourier amplitudes Inline graphic. In simulated annealing Monte Carlo moves, the amplitudes Inline graphic and the boundary positions Inline graphic and Inline graphic are varied. We performed the numerical calculations with up to Inline graphic Fourier modes as in [62], [63]. For any set of parameters Inline graphic, Inline graphic, and Inline graphic, numerical calculations were repeated twice with different initial configurations to ensure convergence to the global minimum.

Spherical cap approximation

To make our model analytically tractable, we approximate the nascent membrane bud by a spherical cap of radius Inline graphic with a budding angle Inline graphic. A convenient budding coordinate is Inline graphic. We also define the area ratio Inline graphic where Inline graphic and Inline graphic denote the areas of the lipid-segregated domain Inline graphic and the ESCRT-rich domain Inline graphic, respectively. The domain of the two dimensionless parameters Inline graphic and Inline graphic is the unit square. In the following, we write the energy of the bud in terms of Inline graphic and Inline graphic, considering two cases:

Case I: The whole lipid-segregated domain Inline graphic forms a spherical cap and thus the membrane surface parametrization is given by Inline graphic for Inline graphic with Inline graphic. Then Inline graphic and the energy functional Eq. (6) becomes a two-variable function

graphic file with name pcbi.1002736.e230.jpg (21)

Case II: Only the ESCRT-free membrane patch forms a bud and therefore the membrane surface parametrization is given by Inline graphic for Inline graphic and Inline graphic for Inline graphic with Inline graphic. Then Inline graphic and

graphic file with name pcbi.1002736.e237.jpg (22)

In both cases I and II, the determinant of the Inline graphic Hessian matrix is always negative within the unit square Inline graphic, Inline graphic, which implies that the local minima of Inline graphic can be found only at the square boundaries. A simple analysis of Eqs. (21) and (22) shows that the local minima of the energy function are located only at the corners of the unit square in the Inline graphicInline graphic plane. First, Inline graphic. Second, Inline graphic, and Inline graphic. Third, Inline graphic. We compare these energies to find the global minimum of the energy function and, in this way, construct the phase diagram in Fig. 2.

Point Inline graphic corresponds to the flat membrane state, which is obviously the starting point of the budding process. Point Inline graphic on energy surface Inline graphic corresponds to an ESCRT-coated bud, whereas point Inline graphic on energy surface Inline graphic corresponds to coatless buds with radius Inline graphic. Point Inline graphic corresponds to a coatless membrane bud with finite radius and ESCRTs localized in the neck. Fluorescence microscopy shows that this state is the end point of the ESCRT-induced budding.

The transition from the initial, flat membrane state at point Inline graphic to the end point at Inline graphic occurs spontaneously with no energy barriers if either (i) Inline graphic and Inline graphic, or (ii) Inline graphic and Inline graphic. In case (i), the transition occurs on energy surface Inline graphic. In case (ii), the system evolves on energy surface Inline graphic. In both cases (i) and (ii) the transitions occur from point Inline graphic to Inline graphic along the Inline graphic line and next from point Inline graphic to Inline graphic along the Inline graphic line. We checked that for some parameter combinations, a saddle point can emerge within the unit square, separating local minima at Inline graphic and Inline graphic. However, if the saddle point is in the unit square, it is higher than Inline graphic. We also checked that for positive parameters Inline graphic and Inline graphic, the saddle point cannot merge with point Inline graphic. So the barrier-free path should indeed go from point Inline graphic to Inline graphic to Inline graphic.

In the case Inline graphic, the system stays on energy surface Inline graphic. It is then instructive to analyze the energy landscape Inline graphic as the circular domain Inline graphic grows. As the domain radius increases beyond Inline graphic, the minimum at Inline graphic becomes higher than the energy at Inline graphic. As the domain radius increases to Inline graphic, the barrier between Inline graphic and Inline graphic disappears entirely. However, if Inline graphic, the point Inline graphic is not a local minimum, with an energy already higher than the minimum at Inline graphic. So if budding is induced at the radius Inline graphic, then the ESCRTs either stay on the bud, if Inline graphic, or they coalesce into the neck immediately after bud formation if Inline graphic.

Another budding scenario is possible if Inline graphic and Inline graphic. The system evolves then on energy surface Inline graphic from point Inline graphic to Inline graphic with no energy barriers, which means that flat, ESCRT-coated membrane domains are unstable and small, ESCRT-free buds with radius Inline graphic form spontaneously. The mini-buds induced by a strong binding preference Inline graphic to membrane portions with negative Gaussian curvature are next squeezed bigger by line tension if Inline graphic. The system evolves then from point Inline graphic to Inline graphic. The resulting ESCRT-free buds have a radius Inline graphic. In contrast to the three-stage mechanism, in this budding pathway the ESCRTs never enter the bud lumen.

Acknowledgments

We thank Dr. Thomas Wollert for stimulating discussions.

Funding Statement

This research was supported by a Marie Curie International Outgoing Fellowship within the 7th European Community Framework Programme (B.R.), the Intramural AIDS Targeted Antiviral Program (J.H.H.), and the Intramural Research Program of the NIH, NIDDK (B.R., E.B., J.H.H., G.H.). The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.

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